Journal of Algebra 230, 455᎐473 Ž2000. doi:10.1006rjabr.2000.8321, available online at http:rrwww.idealibrary.com on
Real 2-Regular Classes and 2-Blocks Roderick Gow and John Murray 1 Department of Mathematics, Uni¨ ersity College Dublin, Belfield, Dublin 4, Ireland E-mail:
[email protected],
[email protected] Communicated by Michel Broue´ Received November 2, 1999
Suppose that G is a finite group. We show that every 2-block of G has a defect class which is real. As a partial converse, we show that if G has a real 2-regular class with defect group D and if NŽ D .rD has no dihedral subgroup of order 8, then G has a real 2-block with defect group D. More generally, we show that every 2-block of G which is weakly regular relative to some normal subgroup N has a defect class which is real and contained in N. We give several applications of these results and also investigate some consequences of the existence of non-real 2-blocks. 䊚 2000 Academic Press
1. INTRODUCTION Let G be a finite group and let p be a prime divisor of < G <. If B is a p-block of G, then the complex conjugates of the irreducible characters in B form another p-block, B⬚, of G. We say that B is a real p-block if B s B⬚. In the case that the prime p is 2, it is easy to prove that a real 2-block has at least one real defect class. One of the main results of this paper, Theorem 3.5, shows that in fact an arbitrary 2-block has a real defect class. As a consequence, in order for G to have a 2-block with defect group D, it must have at least one real 2-regular class with defect group D. The converse of this last statement is false. For instance, the symmetric group S4 has a real 2-regular class of defect zero, yet it has no 2-blocks of defect zero. However, Theorem 4.8 establishes the following partial converse: Let D be a 2-subgroup of G and let NŽ D . denote its normalizer in 1 The second author was supported by a Forbairt Postdoctoral Grant while writing this paper.
455 0021-8693r00 $35.00 Copyright 䊚 2000 by Academic Press All rights of reproduction in any form reserved.
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G. Suppose that NŽ D .rD has no dihedral subgroups of order 8. Then G has a 2-block with defect group D if and only if G has a real 2-regular class with defect group D. We conclude Section 4 with a number of examples illustrating the use of this theorem. In Section 5, we investigate blocks in relation to a normal subgroup N. Our main result is that each 2-block of G which is weakly regular relative to N has a real defect class which is contained in N. If N has odd order, this gives the following purely group-theoretic consequence: N contains a conjugacy class of G with a given defect group if and only if N contains a real conjugacy class of G with the same defect group.
2. PRELIMINARIES Much of our notation comes from wNT89x. In particular, we fix a p-modular system Ž K, O , F . for G and assume that K contains a primitive < G
|
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Z O G. The irreducible K-characters of G are partitioned into blocks, with belonging to the block determined by B l e l if and only if
Ž Kq . s Ž Kq . *, for each conjugacy class K of G. Set ⬚Ž z . [ Ž z⬚., for z g ZFG. Then ⬚ is an F-algebra epimorphism, and it is clear that B⬚ l e⬚ l ⬚ is the associated p-block. Moreover, the complex conjugate ⬚ of belongs to B⬚. The defect group of a block is defined in wNT89, Sect. 3.6x. We collect a number of well-known results about p-blocks in the following lemma. LEMMA 2.1. Suppose that B l e l is a p-block of G, with defect group D. Let K be a conjugacy class of G. Then Ž Kq. s 0 F , unless some defect group of K contains D, and  Ž e, Kq. s 0 F , unless K is p-regular and some defect group of K is contained in D. We note that, given a p-block B l e l , there exists at least one class L such that  Ž e, Lq. / 0 F and Ž Lq. / 0 F . Any such L is called a defect class for B. In later sections, we will be concerned with showing the existence of real 2-blocks with a given defect group. For this purpose, the proof of Lemma 1.2 of wG88x may be adapted to show the following result. LEMMA 2.2. Suppose that G has a 2-block with defect group D and let e D denote the sum of the 2-block idempotents of FG with defect group D. Then G has a real 2-block with defect group D if and only if there exists a real 2-regular class K with defect group D for which  Ž e D , Kq. / 0 F . 3. REAL DEFECT CLASSES Brauer characters and principal indecomposable characters are defined in wNT89, Sect. 6.3x. If B is a p-block of G, with defect group D, and if is an irreducible K-character in B, then Ž1.r< G : D < is an element of O . Moreover, there exists at least one irreducible K-character in B for which Ž1.r< G : D < is a unit in O . We say that any such has height zero. The following result is collected from wO66x: PROPOSITION 3.1. Suppose that B l e l is a p-block of G with defect group D. Let K be a p-regular class with defect group D. Then
 Ž e, Kq . s Ž dim Ž B . r< G < < K < . * Ž K ⬚q . . Proof. Let be an irreducible K-character in B which has height zero. Then Ž1.r< K < and Ž1.r Ž1. are elements of O , for each irreducible
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K-character in B. Also, Ž Kq. ' Ž Kq. mod P. Thus, given any element k in K, we have
Ž k. ' '
Ž 1. < K < Ž k. < K < Ž 1. Ž 1. Ž 1.
Ž k.
mod P
mod P .
If is an irreducible Brauer character of G in B then ⌿ will denote the corresponding principal indecomposable character. Now is a ⺪-linear combination of the restrictions of the ordinary irreducible K-characters in B to the p-regular elements of G. So there exist integers r , such that s Ýr , on p-regular elements, where ranges over the irreducible K-characters in B. Thus
Ž k.* s
ž
Ý
gB
r ,
Ž 1. * Ž 1. * Ž k.* s Ž k . *. Ž 1. Ž 1.
/
ž /
Now Ý g B Ž1. Ž ky1 . s Ý g B ⌿ Ž1. Ž ky1 .. So
 Ž e, Kq . s < G
ž
*
Ý
Ž 1 . Ž ky1 .
gB
/
s
Ý
gB
⌿ Ž 1. * Ž ky1 . *,
ž /
taking into account the fact that ⌿ Ž1. p G < G < p for each ⌿. Thus q
 Ž e, K . s
žÝ
gB
dim Ž B . * ⌿ Ž 1. Ž 1. * y1 Ž k .* s Ž ky1 . *. < G < Ž 1. < G < Ž 1.
/
ž
/
The proposition now follows from the fact that Ž K ⬚q .Ž Ž1.r< K <.*.
Ž ky 1 .* s
COROLLARY 3.2. Suppose that B l e l is a 2-block of G with defect group D and that K is a 2-regular class with defect group D. Then  Ž e, Kq. s Ž K ⬚q .. Proof. This follows from Proposition 3.1 and the fact that 1 F is the only non-zero element in the prime field of F. We note in passing that Proposition 3.1 implies the following result of R. Brauer wB76x. COROLLARY 3.3. Suppose that B l e l is a p-block of G with defect group D. Set < G < p s p a and < D < s p d. Then the p-part of dimŽ B . equals p 2 ayd.
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Proof. It follows from the existence of a defect class Žsee the note after Lemma 2.1. and Proposition 3.1 that dimŽ B .r< G < < G : D < is a unit in O . PROPOSITION 3.4. Suppose that B l e l is a 2-block of G with defect group D and let RD denote the union of the real 2-regular classes of G which ha¨ e defect group D. Then Ž RDq. s 1 F and Ý K : RD  Ž e, Kq. s 1 F . Proof. Let K1 , . . . , Ks , denote all the real 2-regular classes of G with T defect group D and let L1 , LT denote all the non-real 1 , . . . , Lt , Lt 2-regular classes of G with defect group D. Taking into account Lemma 2.1, we have s
Ý  Ž e, Kiq . Ž Kiq .
Ž e. s
is1 t
q
Tq q Lq . Ž LjTq . . . j . Ž Lj . q  Ž e, Lj
Ý Ž  Ž e, js1
Then using Corollary 3.2, we get s
Ž e. s
Ý Ž Kiq .
2
t
q
is1
js1 2
s
s
ž
Ý Ž Ž LjTq . Ž Lqj . q Ž Lqj . Ž LjTq . . ,
Ý Ž Kiq . is1
/
,
as F has characteristic 2,
2
s Ž RDq . . Thus 1 F s Ž e . s Ž RDq. 2 , which in turn implies that Ž RDq. s 1 F . The second equation now follows from Corollary 3.2. We now present the main result of this section. THEOREM 3.5.
E¨ ery 2-block has a real defect class.
Proof. Let B l e l be a 2-block of G which has defect group D. It follows from the previous theorem that there exists a real 2-regular class K of G, with defect group D, such that Ž Kq. / 0 F . But  Ž e, Kq. / 0 F , using Proposition 3.1. So K is a real defect class for B. The result follows. Our corollary furnishes a necessary condition for the existence of 2-blocks which seems to have been overlooked until now. COROLLARY 3.6. Suppose that G has a 2-block with defect group D. Then G has a real 2-regular conjugacy class with defect group D.
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EXAMPLE 3.7. Let n ) 1 be an odd integer and let q be a power of an odd prime p. Suppose that n is relatively prime to q y 1. Consideration of rational canonical forms shows that the only real 2-regular class of defect zero in the simple group SL nŽ q . is that containing a regular unipotent element, whose minimal polynomial is Ž x y 1. n. It is known that SL nŽ q . has 2-blocks of defect 0, so the class of regular unipotent elements is the only real defect class for such blocks. Taking n s 3 and gcdŽ3, q y 1. s 1, we find that the number of 2-blocks of defect 0 is q Ž q q 1.r3. Each of these blocks contains a unique irreducible character of degree Ž q y 1. 2 Ž q q 1., which is not real-valued, and they all have the same real defect class, consisting of elements of order p. Let B l e l be a real 2-block of G with defect group D. Suppose that Ž Kq. / 0 F and Ž Lq. / 0 F , where K and L are real classes of G and K has defect group D. The first author showed wG88, 2.1x that each extended defect group of K is contained in some extended defect group of L , thus refining Lemma 2.1. This need not hold when B is non-real, as the following example shows: EXAMPLE 3.8. Let Sn Ž An . denote the symmetric Žalternating . group of degree n. Suppose that n s mŽ m q 1.r2 is a triangular number, where m ) 0. Then Sn has a 2-block of defect zero, containing the irreducible character corresponding to the triangular partition w m, . . . , 3, 2, 1x. Let be an irreducible constituent of the restriction of this character to An . Then lies in a 2-block B of defect zero. Now suppose that m is even and greater than 2. The classes of cycle type wŽ2 m y 3. 2 , 2 m y 9, 2 m y 13, 2 m y 17, . . . x, and w2 m y 1, 2 m y 5, . . . , 7, 13 x, if m ' 2 mod 4, of Sn form single classes K and L of An . Moreover both have defect 0, and are real in An , elements being inverted by involutions of cycle type 2 Ž m r2. , 2
for K , if m ' 0 mod 4;
2 Ž m r2.
2
q1
,
for K , if m ' 2 mod 4;
2 Ž m r2.
2
y1
,
for L , if m ' 2 mod 4.
By repeated applications of the Murnaghan᎐Nakayama formula, it can be shown that takes the value "1 on elements of K or L . So K, and L if m ' 2 mod 4, are real defect classes for B. However, K and L are inverted by non-conjugate involutions.
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4. EXISTENCE OF REAL 2-BLOCKS Given a p-subgroup D of G, we will write e D s e D Ž G . for the sum of the block idempotents of FG with defect group D. In the case that D is the trivial subgroup of G, we will write e0 s e0 Ž G . for the sum of the block idempotents of defect 0. Similar notation will be used for subgroups of G. We will also write R0 s R0 Ž G . for the union of the real p-regular classes which have trivial defect group. Set W [ NŽ D .rD, and let : F NŽ D . ª FW be the F-algebra epimorphism induced by the natural group epimorphism : NŽ D . ª W. LEMMA 4.1. Suppose that k is a p-regular element of G with p-defect group D. Then  Ž e D Ž G ., k . s  Ž e0 ŽW ., Ž k ... Proof. Let B l e l be a p-block of G with defect group D. Brauer’s first main theorem establishes a bijection between the p-blocks of G with defect group D and the p-blocks of NŽ D . with defect group D. Let B˜ l ˜ el ˜ correspond to B l e l under this bijection. It follows from Theorem 5.2.15 of wNT89x that
 Ž e, k . s  Ž ˜ e, k . .
Ž 4.2.
Suppose that k lies in the class K of NŽ D . and that Ž k . lies in the class L of W. Then K is p-regular with p-defect group D. So by wNT89, Lemma 5.8.9x we have Ž Kq. s Lq. It follows that
Ž˜ e, Kq . s  Ž Ž ˜ e . , Lq . .
Ž 4.3.
Theorem 5.8.7Žii. of wNT89x implies that Ž ˜ e . is a sum of p-blocks of W with trivial defect group. Hence
Ž˜ e. s Ž ˜ e . e0 Ž W . .
Ž 4.4.
Suppose that BW l eW l W is a p-block of W, with trivial defect group, such that  Ž eW , Lq. / 0 F . Then W ( : ZF NŽ D . ª F is an F-algebra epimorphism. Let BN l e N l N be the associated p-block of NŽ D .. Then
N Ž K ⬚q . s W ( Ž K ⬚q . s W Ž L ⬚q . s ⭈  Ž eW , Lq . ,
where / 0 F ,
by Proposition 3.1 and Corollary 3.3 / 0F ,
as  Ž eW , Lq . / 0 F .
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It follows from Lemma 2.1 that some defect group of BN is contained in D, the unique p-defect group of K ⬚. But D is a normal p-subgroup of NŽ D .. So every defect group of BN contains D. We deduce that BN is a p-block with defect group D. Also N Ž Ž eW .. s W Ž eW . s 1 F . So eW s eW Ž e N .. The result now follows from Ž4.2., Ž4.3., and Ž4.4.. We take p to be 2 for the rest of this section and for each positive integer n, we set Qn s QnŽ G . [ g g G ¬ g has order n4 . LEMMA 4.5.
e0 s R0qq Q4qq Q4qQ 2q.
Proof. This follows from the equalities 2 Ž 1 G q Q2q . s R0q,
Ž 1G q
Q2qq
Q4q
. Ž 1G q
Q2q
. s e0 ,
by Proposition 4.1 of w M99x by Corollary 5.9 of w M99x .
If g is a real element of G of defect zero, then it is well known that there exists an involution t which inverts g. So s [ gt is also an involution which inverts g. Moreover, if g s u¨ , where u and ¨ are involutions, then both u and ¨ invert g. Any two involutions which invert g are conjugate in C*Ž g ., and hence come from a single conjugacy class of involutions in G. We will use D 8 to denote a dihedral group of order 8 and K 4 to denote an elementary abelian group of order 4. PROPOSITION 4.6. Suppose that g is a real element of G which has tri¨ ial defect group. Let s and t be in¨ olutions such that g s st. Then
 Ž e0 , g . s 1 F q u g Q2 ¬ ² s, u: ( D 8 , ² u, t : ( K 4 4 1 F . Proof. It follows from Lemma 4.5 that
 Ž e0 , g . s 1 F q ⌽ 1Ž g . 1 F , where ⌽ 1Ž g . [ Ž x, y . g Q4 = Q2 ¬ xy s g 4 . Define Ž x, y . t [ Ž xyy t , y t ., for Ž x, y . g ⌽ 1Ž g .. We check that Ž x, y . t g ⌽ 1Ž g . and that ŽŽ x, y . t . t s Ž x, y .. In this way we get an action of the 2-group ² t : on ⌽ 1Ž g .. Each orbit of ² t : on ⌽ 1Ž g . has size 1 or 2. So
 Ž e0 , g . s 1 F q ⌽ 2 Ž g . 1 F ,
Ž 4.7.
where ⌽ 2 Ž g . [ Ž x, y . g Q4 = Q2 ¬ xy s g, x s xyy t , y s y t 4 . Set ⌽ 3 Ž g . [ u g Q2 ¬ ² s, u: ( D 8 , ² u, t : ( K 4 4 . Suppose that Ž x, y . g ⌽ 2 Ž g . and u g ⌽ 3 Ž g .. We check that yt g ⌽ 3 Ž g . and Ž su, ut . g ⌽ 2 Ž g ..
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Moreover the maps ⌽ 2 Ž g . ª ⌽ 3 Ž g ., Ž x, y . ª yt and ⌽ 3 Ž g . ª ⌽ 2 Ž g ., u ª Ž su, ut . are inverse of each other. Thus < ⌽ 2 Ž g .< s < ⌽ 3 Ž g .<. The proposition now follows from Ž4.7.. In a similar fashion we can show, with the notation above, that
 Ž e0 , g . s 1 F q u g Q2 ¬ ² s, u: ( ² u, t : ( D 8 4 1 F s 1 F q Ž u, ¨ . g Q2 = Q2 ¬ ² s, u: ( ² u, ¨ : ( ² ¨ , t : ( K 4 4 1 F . The next result, which uses Proposition 4.6 in a crucial way, gives a partial converse to Corollary 3.6 and also generalizes Theorem 2 of wT71x. THEOREM 4.8. Suppose that no subgroup of W [ NŽ D .rD is isomorphic to D 8 . Then  Ž e D Ž G ., g . s 1 F , for each real 2-regular element g with defect group D. In particular, the following are equi¨ alent: Ž a. G has a real 2-regular element with defect group D; Žb. G has a 2-block with defect group D; Žc. G has a real 2-block with defect group D. Proof. We have
 Ž e D Ž G . , g . s  Ž e0 Ž W . , Ž g . . , s 1F ,
by Lemma 4.1
using the hypothesis and Proposition 4.6.
This proves the first assertion. Suppose that G has a real 2-regular element g with defect group D. Then  Ž e D Ž G ., g . s 1 F . So G has a real 2-block with defect group D, by Lemma 2.2. Thus Ža. « Žc.. The implication Žc. « Žb. is trivial. The implication Žb. « Ža. follows from Corollary 3.6. This completes the proof. In the situation of Theorem 4.8, we can sometimes guarantee the existence of more than one block with defect group D. COROLLARY 4.9. Suppose that no subgroup of W [ NŽ D .rD is isomorphic to D 8 . Suppose further that G has r real 2-regular classes, K1 , . . . , Kr , with defect group D, which ha¨ e non-conjugate extended defect groups. Then G has at least r distinct real 2-blocks with defect group D. Proof. It follows from Theorem 4.8 that  Ž e D Ž G ., Kiq. s 1 F , for i s 1, . . . , r. Corollary 3.2 implies that if 1 F i F r, then G has a 2-block Bi l e i l i with defect group D such that i Ž Kiq. / 0 F . Moreover, as in the proof of Lemma 2.2, we may choose each Bi to be real.
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As the principal 2-block is the only real 2-block with maximal defect, and the trivial class is the only real class with maximal defect, we may assume that D is not a Sylow 2-subgroup of G. It then follows from Corollary 2.2 of wG88x that Bi / Bj , for all distinct i, j from 1, . . . , r 4 . This completes the proof. Note 4.10. The condition that no subgroup of W is isomorphic to D 8 is equivalent to the condition that all the involutions in a Sylow 2-subgroup of W commute with each other and thus generate an elementary abelian 2-subgroup of W. Corollary 1 of wGL74x, taken in conjunction with later work of Bombieri and Thompson on the classification of groups of Ree type, implies that if G is a simple group with no subgroup isomorphic to D 8 , G is isomorphic either to a group of Lie type of rank 1 over a field of even characteristic, or to PSL 2 Ž q ., where q ' 3, 5 mod 8 and q ) 3, or to the Janko group J1 , or to a Ree group 2 G 2 Ž3 2 nq1 .. Excluding the group PSL 2 Ž2 2 . which is isomorphic to PSL 2 Ž5., the groups of Lie type of rank 1 over a field of even characteristic are PSL 2 Ž2 n ., n G 3, SzŽ2 2 nq1 ., n G 1, and PSU3 Ž2 n ., n G 2, and each of these groups has a unique 2-block of defect 0, which contains the Steinberg character. We say that D is a maximal Sylow 2-intersection in G if D s S l T, where S / T are Sylow 2-subgroups of G, and if D F P l Q, where P / Q are Sylow 2-subgroups of G, then D s P l Q. The following is a special case of Theorem 4.8. COROLLARY 4.11. Suppose that D is a maximal Sylow 2-intersection in G. Then the conditions Ža., Žb., and Žc. of Theorem 4.8 are equi¨ alent for G. Proof. The hypothesis implies that W s NŽ D .rD has a trivial intersection Sylow 2-subgroup. An elementary argument Ždue to M. Suzuki. shows that W has no subgroups isomorphic to D 8 . The result now follows from Theorem 4.8. Our next corollary can also be proved using the Brauer᎐Suzuki theorem, but the methods developed in this section provide a self-contained approach. COROLLARY 4.12. Suppose that a Sylow 2-subgroup of G is generalized quaternion or cyclic. Then either G has a unique in¨ olution or it has a real 2-block of defect 0. Proof. Suppose that G has two different involutions s and t. Consider their product st. This is not the identity. We claim that st has odd order. For if this is not the case, there exists an involution u which commutes with both s and t. This contradicts the fact that G contains no elementary abelian subgroup of order 4. Thus st has odd order. Also st is real, since it is inverted by t.
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Let S be a Sylow 2-subgroup of the extended centralizer C*Ž st . of st which contains t. Then t is the unique involution in S, but t f CŽ st .. Since CŽ st . l S is a Sylow 2-subgroup of CŽ st ., it follows that this latter group has odd order. In particular st has defect zero. Finally, as a Sylow 2-subgroup contains no dihedral subgroup of order 8, it follows from Theorem 4.8 that G has a real 2-block of defect 0. The Brauer᎐Suzuki theorem gives the more precise information that any real defect zero element of G lies in O 2 ⬘Ž G .. This strengthens wT74, Proposition 5x. COROLLARY 4.13. Suppose that G does not possess subgroups H and K with H e K and KrH ( D 8 . Then all 2-blocks of G ha¨ e maximal defect if and only if G has a normal Sylow 2-subgroup. Proof. Let S be a Sylow 2-subgroup of G. We may suppose that < S < ) 1. Theorem 4.8 implies that all 2-blocks of G have maximal defect if and only if G has no non-identity real 2-regular elements. Now if S is normal in G, it is elementary to check that G has no non-identity real 2-regular elements. Conversely, suppose that G has no non-identity real 2-regular elements. Then G [ GrO2 Ž G . also has no non-identity real 2-regular elements. We claim that G has odd order. Let s and t be involutions in G. Then s inverts every element in ² st : and hence st has 2-power order. It follows from the hypothesis on the subgroups of G that Ž st . 2 s 1. In particular s and t commute. So the involutions in G form a normal 2-subgroup. We conclude that G has no involutions, which proves our claim. The following result, which generalizes wH68x, is a special case of the previous corollary. THEOREM 4.14. Suppose that a Sylow 2-subgroup S of G is abelian, or is a direct product of a quaternion group of order 8 with an elementary abelian 2-group. Then all 2-blocks of G ha¨ e maximal defect if and only if S is normal in G. The groups S in the theorem above are precisely the Dedekind 2-groups, i.e., those 2-groups all of whose subgroups are normal.
5. BLOCKS AND NORMAL SUBGROUPS Let N be a normal subgroup of G. We say that a p-block B l e l of G co¨ ers a p-block b l e b l b of N if the restriction of some irreducible character in B has an irreducible constituent in b. It can be shown that each block of G covers a G-orbit of blocks of N. More
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precisely B covers b if and only if e s ee bG , where e bG denotes the sum of the distinct G-conjugates of e b in G. We will use BlŽ G < b . to denote the set of blocks of G which cover b. Suppose now that B covers b. We say that B is weakly regular Žrelative to N . if it has maximal defect among the blocks of G which cover b. It follows from Theorem 5.5.16 of wNT89x that the weakly regular blocks in BlŽ G < b . have a common defect group, D say. Moreover, D l N is a defect group of b and DNrN is a Sylow p-subgroup of I Ž b .rN, where I Ž b . is the inertial subgroup of b in G. We call D a defect group of b in G. Those blocks in BlŽ G < b . which are not weakly regular have defect groups strictly contained in D. We now specialize to p s 2. LEMMA 5.1. Suppose that b l e b l b is a 2-block of N. Then the number of weakly regular blocks which co¨ er b is odd and
 Ž e bG , Kq . s Ž K ⬚q . , for each 2-block B l e l of G which co¨ ers b and each 2-regular class K of G which is contained in N and which has defect group D. Proof. Let Bi l e i l i , 1 F i F s, be a complete list of the blocks of G which cover b, ordered so that B1 , . . . , Bt are all the weakly regular blocks. It follows from Theorem 5.5.5 of wNT89x that
i Ž Kq . s j Ž Kq . ,
Ž 5.2.
for each class K of G which is contained in N, and each pair i, j g 1, . . . , s4 . So we can assume, and we do, that B is weakly regular. We may write e1 q ⭈⭈⭈ qe s s e bG s
Ý  Ž ebG , Kq . Kq,
Ž 5.3.
where K ranges over the 2-regular classes of G which are contained in N. Since B covers b, we have 1 F s Ž e . s Ž e bG . s
Ý  Ž ebG , Kq . Ž Kq . .
Ž 5.4.
It follows that there is at least one 2-regular class L contained in N with
 Ž e bG , Lq . / 0 F
and
Ž Lq . / 0 F .
As B has defect group D, we deduce from Lemma 2.1 that D is contained in a defect group of L . Furthermore, it follows from Ž5.3. that there is an index j, with 1 F j F s, such that  Ž e j , Lq. / 0 F . Since Bj has a defect group contained in D, Lemma 2.1 implies that so too does L . We conclude that L has defect group D.
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Now Bi has defect group D, for 1 F i F t, and Bi has a defect group strictly contained in D, for t - i F s. So
 Ž e i , Lq . s
½
i Ž L ⬚q . , 0F ,
for 1 F i F t , by Proposition 3.1, for t - i F s, by Lemma 2.1.
It follows that
 Ž e bG , Lq . s
t
Ý Ž L ⬚q . s t* Ž L ⬚q . ,
using Ž 5.3. and Ž 5.2. .
is1
In particular, t is odd. Finally, if K is any 2-regular class of G with defect group D that is contained in N, identical arguments now show that  Ž e bG , Kq . s Ž K ⬚q .. Easy examples show that the following corollary is false when p / 2. COROLLARY 5.5. Suppose that b l e b l b is a 2-block of N. Then b is G-conjugate to b⬚ if and only if some real weakly regular 2-block of G co¨ ers b. Proof. The ‘‘if’’ part of this statement is straightforward. Suppose that b is G-conjugate to b⬚, and that B l e l is a 2-block of G which covers b. Then B covers b⬚. So
⬚ Ž Kq . s Ž K ⬚q . s Tb Ž K ⬚q . s b Ž Kq . , for each class K of G which is contained in N, using wNT89, Theorem 5.5.5x. It follows that BT covers b, again using wNT89, Theorem 5.5.5x. Now B is weakly regular if and only if BT is weakly regular. So the number of non-real weakly regular blocks in BlŽ G < b . is even. We deduce from Lemma 5.1 that there are an odd number of real weakly regular blocks in BlŽ G < b ., proving the ‘‘only if’’ part. We let RDN denote the union of the real 2-regular classes of G which have defect group D and which are contained in N. The following result generalizes Proposition 3.4: PROPOSITION 5.6. Suppose that b l e b l b is a 2-block of N with defect group D in G. Then Ý K : RDN  Ž e bG , Kq . s 1 F . Also Ž RDNq . s 1 F , for each 2-block B l e l of G which co¨ ers b.
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Proof. We have
Ý  Ž ebG , Kq . Ž Kq . , s Ý Ž K ⬚q . Ž Kq . ,
1F s
by Ž 5.4. , by Lemma 5.1,
where K ranges over the 2-regular classes of G which have defect group D and which are contained in N. The proof now proceeds along the same lines as that of Proposition 3.4. We can now prove the following generalization of Theorem 3.5: THEOREM 5.7. E¨ ery 2-block of G which is weakly regular relati¨ e to N has a real defect class which is contained in N. Proof. This follows immediately from Propositions 3.1 and 5.6. The aim of the remainder of this section is to prove Theorem 5.10. This result, which is concerned with the reality of elements in a non-trivial normal subgroup of odd order, does not appear to have a purely grouptheoretic proof. The basic idea for the next lemma goes back to wBF55, Theorem 5Ex and was also used in our context by wW77x. LEMMA 5.8. Let N be a normal subgroup of odd order in G. E¨ ery conjugacy class of G which is contained in N is a defect class for some real weakly regular 2-block of G. Proof. Let K be a conjugacy class of G which is contained in N, and let k be an element of K. We define a class function of G by
[
Ý Ž K ⬚q . Ž k . ,
where ranges over the K-irreducible characters of G. Let P be a Sylow 2-subgroup of G and let g be a non-identity element of P. Since no conjugate of g can be expressed as a product of elements of N, it follows that Ž g . s 0. See, for example, wI94, Problem 3.9x. Also Ž1. s < G <. So
Ž 1. s Ž P , 1P . s < P<
Ý Ž K ⬚q . Ž k . Ž P , 1 P . ,
where P denotes the restriction of to P, and 1 P denotes the principal character of P. Also Ž K ⬚q . Ž k . s ⬚Ž K ⬚q . ⬚Ž k . and Ž P , 1 P . s Ž P ⬚, 1 P ., for each , where ⬚ denotes the complex conjugate of . It
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follows that
Ý Ž K ⬚q . Ž k . Ž P , 1 P .
mod P ,
where ranges over the real K-irreducible characters of G. Since < G : P < is odd, there must be a real-valued irreducible K-character with Ž k . k 0 mod P, Ž K ⬚q . k 0 mod P, and Ž , 1 P .P an odd integer. Let B l e l be the, necessarily real, 2-block of G which contains . Since Ž k . k 0 mod P and Ž K ⬚q . k 0 mod P, it follows that K is a defect class for B. So B is weakly regular, using the definition of weak regularity given in wNT89, Sect. 5.5x. The following corollary is a straightforward application of a result of P. Fong. COROLLARY 5.9. Suppose that G is sol¨ able. Then G has a 2-block of non-maximal defect if and only if G has a real non-principal 2-block. Proof. Any real non-principal 2-block necessarily has non-maximal defect. On the other hand, suppose that G has a 2-block of non-maximal defect. Then the 2-regular core O 2 ⬘Ž G . of G contains a class K of non-maximal defect, by wF62, Theorem Ž1G.Žii.x. Thus G has a real 2-block of non-maximal defect, using the previous lemma. We note that Corollary 5.9 need not hold for a group that is not solvable. For example, the Mathieu group M11 has exactly three 2-blocks, namely, the principal block and two non-real blocks of defect 0. Theorem 6.6 of this paper shows that this phenomenon can only occur in a group whose Sylow 2-subgroup has order at least 16 Žthe Sylow 2-subgroup of M11 has order 16.. We now prove our main result on the existence of real elements in normal subgroups of odd order. THEOREM 5.10. Let N be a normal subgroup of G which has odd order, and let D be a 2-subgroup of G. Then G has a conjugacy class with defect group D which is contained in N if and only if G has a real conjugacy class with defect group D which is contained in N. Proof. Suppose that G has a conjugacy class which is contained in N and which has defect group D. Then G has a real 2-block B which is weakly regular and which also has defect group D, using Lemma 5.8. So N contains a real defect class for B, by Theorem 5.7. This class has defect group D. The result follows.
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6. NON-REAL 2-BLOCKS Let GD denote the union of the 2-regular classes of G which have defect group D. The following result is similar to Proposition 3.4: PROPOSITION 6.1. group D. Then
Suppose that B l e l is a 2-block of G with defect
Ž Gq D. s
½
if s ⬚; if / ⬚.
1F , 0F ,
Proof. We have
Ž e⬚ . s
Ý  Ž e⬚, Kq . Ž Kq . ,
where K ranges over the 2-regular classes with defect group D. Using Corollary 3.2, we have
Ž e⬚ . s
Ý Ž K . 2 s Ž Ý Ž Kq . .
2
2
s Ž Gq D. .
The proposition follows from the fact that
Ž e⬚ . s
½
1F , 0F ,
if s ⬚; if / ⬚.
This result can be used to gain additional group-theoretic information when G has a non-real 2-block whose defect group is not a Sylow 2-subgroup of G. Let G 2 ⬘ denote the set of 2-regular elements of G. We begin with the proof of a result that is quite well known. LEMMA 6.2. Suppose that B l e l is a non-principal 2-block of G. . Then Ž Gq 2⬘ s 0F . Proof. Let be an irreducible K-character in B, and let d be the defect of B. We define a class function on G by setting
Ž g. [
½
2 d Ž g . , 0,
if g g G 2 ⬘ ; if g g G _ G 2 ⬘ .
It is known that is an integral combination of the irreducible K-characters in B. See, for example wNT89, Lemma 3.6.33Ži.x. Since B is not the
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principal block, Ž , 1 G . s 0, where 1 G is the principal character of G. It . Ž q. follows that Ž Gq 2 ⬘ s 0, and hence that G 2 ⬘ s 0. The result follows. We proceed to the main result of this section. THEOREM 6.3. Suppose that B l e l is a non-real 2-block of G whose defect group D is not a Sylow 2-subgroup of G. Then there exists a non-identity 2-regular class K of G, whose defect group strictly contains D, such that Ž Kq. / 0 F . Proof. Certainly B is not the principal block of G Žas B / B⬚.. So Ž . Ž q. s 0 F , if a defect group Gq 2 ⬘ s 0 F , by the previous lemma. Now K . of a class K does not contain D, using Lemma 2.1. Moreover, Ž Gq D s 0F , Ž . by Proposition 6.1, and 1 G s 1 F . Since D is not a Sylow 2-subgroup of G, it follows that Ý Ž Kq. s 1 F , where K ranges over the non-identity 2-regular conjugacy classes of G that have a defect group which strictly contains D. The result follows. Theorem 4.8 shows that, in certain circumstances, the existence of a non-real 2-block with defect group D implies the existence of a real 2-block with the same defect group. We end this section by considering an extension of this idea. The proof of the following result relies on transfer techniques. We omit the details, which are well known. LEMMA 6.4. Suppose that the finite group G has a dihedral Sylow 2-subgroup. Let t be an in¨ olution in G. Then CŽ t . has a normal 2-complement. While we are primarily interested in the prime 2, the next result, giving a sufficient condition for the existence of a non-principal p-block, holds for any prime p. PROPOSITION 6.5. Let D be a p-subgroup of G and let E be a p-subgroup of NŽ D . containing D which is not a Sylow p-subgroup of NŽ D .. Set W [ NŽ D .rD. Suppose that G has a p-regular class with defect group E and that NW Ž ErD . has a normal p-complement. Then G has a non-principal p-block BG which has a defect group containing E. Proof. Recall that : F NŽ D . ª FW is the F-algebra epimorphism induced by the natural group epimorphism : NŽ D . ª W. Let k be a p-regular element of G which has defect group E, let K be the conjugacy class of NŽ D . which contains k, and let L be the conjugacy class of W which contains Ž k .. Then, as in Lemma 4.1, the class L has defect group J [ ErD in W and Ž Kq. s Lq. Set H s NW Ž J .. Now L l C W Ž J . is a p-regular class of H which has defect group J, and by hypothesis H has a normal p-complement. Using
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wT77, Theorem 1x, we see that H has a p-block BH l H , with defect group J, such that H ŽŽ L l C W Ž J ..q. / 0 F . Brauer’s first main theorem then implies that W has a p-block BW l W , with defect group J, such that W Ž Lq. / 0 F . Let BN l N be the unique p-block of NŽ D . which dominates BW , and let R be a defect group of BN . Then R contains D, by a theorem of Brauer, and J is conjugate in W to a subgroup of RrD, by wNT89, Theorem 5.8.7 Žii.x. Since ErD s J, this implies that E is conjugate in NŽ D . to a subgroup of R. Also N Ž Kq. s W ( Ž Kq. s W Ž Lq. / 0 F . So some conjugate of R is contained in E, the defect group of L . It follows that BN has defect group E. Since ECŽ E . F NŽ D ., wNT89, Corollary 5.3.7x guarantees that the induced block BG [ BNG is defined. But BN is not the principal p-block of NŽ D ., since E is not a Sylow p-subgroup of NŽ D .. So BG is not the principal p-block of G, by Brauer’s third main theorem Žsee wNT89, Theorem 5.6.1x.. Finally, it is a standard fact that some defect group of BG contains E. THEOREM 6.6. Suppose that G has a non-real 2-block with defect group D, such that a Sylow 2-subgroup of W [ NŽ D .rD has order 8. Then G either has a real 2-block with defect group D or it has a non-principal 2-block with defect group strictly containing D. Proof. Proposition 4.6 implies G has a real 2-block with defect group D unless possibly W has a dihedral Sylow 2-subgroup. We may therefore suppose that W has a dihedral Sylow 2-subgroup of order 8. Now Theorem 6.3 implies that NŽ D . has a non-trivial 2-regular element g with defect group E strictly containing D. If E is a Sylow 2-subgroup of NŽ D ., then NŽ D . and hence G has a non-principal 2-block with defect group strictly containing D. If E has defect 1 less than maximal, then a standard argument shows that NŽ D . has a non-principal 2-block with defect group E, and hence G has a non-principal 2-block with defect group strictly containing D. If w E : D x s 2, then NW Ž ErD . has a normal 2-complement, using Lemma 6.4. So NŽ D . has a real non-principal 2-block whose defect group contains E, by Proposition 6.5. It follows that G has a real non-principal 2-block with a defect group which strictly contains D. REFERENCES wB76x R. Brauer, Notes on representations of finite groups, I, J. London Math. Soc. 90 Ž1976., 162᎐166. wBF55x R. Brauer and K. A. Fowler, On groups of even order, Ann. Math. 62 Ž1955., 565᎐583.
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P. Fong, Solvable groups and modular representation theory, Trans. Amer. Math. Soc. 103 Ž1962., 484᎐494. wGL74x D. M. Goldschmidt, 2-Fusion in finite groups, Ann. Math. 99 Ž1974., 70᎐117. wG88x R. Gow, Real 2-blocks of characters of finite groups, Osaka J. Math. 25 Ž1988., 135᎐147. wH68x K. Harada, On groups all of whose 2-blocks have the highest defects, Nagoya Math. J. 32 Ž1968., 283᎐286. wI94x I. M. Isaacs, ‘‘Character Theory of Finite Groups,’’ Dover, New York, 1994. wM99x J. Murray, Blocks of defect zero and products of elements of order p, J. Algebra 214 Ž1999., 385᎐399. wNT89x H. Nagao and Y. Tsushima, ‘‘Representations of Finite Groups,’’ English ed., Academic Press, New York, 1989. wO55x M. Osima, Notes on blocks of group characters, Math. J. Okayama Uni¨ . 4 Ž1955., 175᎐188. wO66x M. Osima, On block idempotents of modular group rings, Nagoya Math. J. 27 Ž1966., 429᎐433. wT71x Y. Tsushima, On the block of defect zero, Nagoya Math. J. 44 Ž1971., 57᎐59. wT74x Y. Tsushima, On the existence of characters of defect zero, Osaka J. Math. 11 Ž1974., 417᎐423. wT77x Y. Tsushima, On the weakly regular p-blocks with respect to Op⬘Ž G ., Osaka Math. J. 14 Ž1977., 465᎐470. wW77x T. Wada, On the existence of p-blocks with given defect groups, Hokkaido Math. J. 6 Ž1977., 243᎐248.